Angle Closure and Angle Closure Glaucoma - part 5 pptx

In a comparative non-randomized study of lens extraction against filtering surgery for angle closure glaucoma, Gunning & Greve found that fil-tering surgery yielded better long-term glau

the surgical options for PACG are diverse These include filtering surgery alone, lens extraction alone, combined lens extraction and filtering surgery, angle widening procedures such as goniosynechialysis, and an angle widening procedure

com-bined with lens extraction Other considerations include the method of lens

extraction, be it phacoemulsification or ECCE, the use of antimetabolites, and

the number and choice of surgical sites in filtering surgery Randomized

con-trolled trials are necessary to evaluate these types of surgery in PACG

Trabeculectomy

The indications for trabeculectomy in PACG are the same as in POAG These include inadequate control of IOP (despite LPI), continuing optic disc/visual field damage and intolerance to medical therapy The indications for the use of anti-scarring agents are also similar to that of POAG, namely eyes at high risk

of failure of surgery (such as those with previous failed trabeculectomy), those with advanced disease (extensive PAS, optic nerve damage and visual field loss) and those on multiple medications In many centers, anti-scarring agents are used routinely for all trabeculectomies

There have been no randomized controlled trials published to date for trabeculectomy in PACG A retrospective study from India showed that trabeculectomy without antimetabolite use appears to be efficacious in lower-ing IOP and in visual field preservation over a period of ten years in patients with PACG, with similar outcomes as POAG About a third of PACG cases had a two-line decrease in visual acuity due to the development of a cataract.26

In eyes with PACG, malignant glaucoma is commonly cited as a possible complication following trabeculectomy However, this was not observed in a

study by Watson et al conducted in the UK, which showed similar

complica-tion rates to POAG and angle closure eyes.27

Lens extraction alone

It is believed that the size and position of the lens plays a major role in the pathogenesis of PACG.1,5 With aging, there is an increase in the thickness of the lens and a more relatively anterior lens position In eyes which are hyperopic with small anterior segments, this effect is likely to be accentuated and the result

is crowding in the angles and a greater predisposition to pupillary block.28-29 Lens extraction with posterior chamber intraocular lens implantation has been found to result in satisfactory IOP control postoperatively in eyes with PACG.30-34 It is postulated that the deepening of the anterior chamber results

in a reduction of angle crowding and relief of relative pupil block A study employing Scheimpflug video photography to study the angle, showed that the width and depth of the angle in eyes with PACG increased significantly after

phacoemulsification, and became similar to that in eyes with open angles.35 In addition, lens extraction may lower IOP36 and reduce the likelihood of progres-sive angle closure and a chronic rise in IOP

Problems encountered after cataract surgery in patients with PACG include significant inflammation and transient elevations in IOP in the immediate post-operative period.30-31 This IOP spike may be dangerous for eyes with advanced visual field loss Furthermore, many eyes require a second surgery later to control IOP In a comparative non-randomized study of lens extraction against filtering surgery for angle closure glaucoma, Gunning & Greve found that fil-tering surgery yielded better long-term glaucoma control than cataract surgery alone (lower IOP and less ocular hypotensive medication) but was accompa-nied by more complications and deterioration in visual function due to subse-quent development of cataract.33 Lens removal also does not remove the risk

of angle closure in eyes with plateau iris syndrome

Cataract surgery in PACG eyes (especially those with previous APAC) is technically difficult The anterior chamber is usually shallow, the lens often bulky and the pupil is frequently small from miotic treatment or ischaemic iris atrophy Excessive curvature of the anterior capsule may also predispose to tears Iris ischemia from a previous acute episode may render the iris flaccid, which together with a small pupil, may make the iris more susceptible to trauma during surgery Hooks can be used to deal with small pupils Corneal decom-pensation is another potential long-term complication For cases of previous APAC, the corneal endothelium already at risk of damage from the acute epi-sode may undergo further injury from phacoemulsification leading to higher risk of decompensation PACG eyes may also be at higher risk of lens sublux-ation or zonular weakness as well as aqueous misdirection during and after surgery

Combined cataract and trabeculectomy surgery

Combined phacoemulsification, intraocular lens implantation and trabeculectomy

is another option in the surgical management of PACG This procedure offers the advantages of visual rehabilitation after cataract extraction, prevention of IOP spikes in the immediate post-operative period, and widening of the angle after lens removal with improved IOP control The combined procedure exposes the patient to a single surgical experience, saving on the ‘opportunity cost’ of operating room time The use of adjunctive antimetabolites in combined surgery has further increased the surgical options available

However, data are limited on the outcome of such surgery for PACG A retrospective study from Singapore showed that combined phacoemulsification with posterior chamber intraocular lens implantation and trabeculectomy was associated with good IOP control and visual outcome in patients with PACG There were no intraoperative complications in this series and the incidence of

post-operative complications was also low.37 Another study found that the com-plication rates of phacotrabeculectomy were similar in PACG and POAG pa-tients.38

Other forms of surgery

Surgical iridectomy alone

Surgical iridectomy alone has a limited role in the current management of PACG

It may be performed when lasers are not available or for patients who are unco-operative/unsuitable for LPI

Goniosynechialysis with cataract extraction

Goniosynechialysis, an angle-widening procedure, is another surgical option for treatment of PACG.39 It has also been combined with cataract extraction in eyes with previous acute angle closure.40 In this procedure, PAS are physically stripped from the angle wall, opening the angle and restoring trabecular function There are limited data on the long-term effectiveness of this procedure for PACG It

is thought that goniosynechialysis may more likely be successful if the syn-echiae have been present for less than one year

Glaucoma implants

Glaucoma drainage implant surgery is usually performed in eyes with refrac-tory glaucoma with high risk of failure of conventional trabeculectomy In retro-spective studies, drainage implants have been demonstrated to work in PACG eyes with previous failed trabeculectomy,41 as well as when combined with lens extraction.42

Cyclodestructive procedures

Cyclodestructive procedures are used for PACG eyes with end stage disease without visual potential, and are symptomatic due to high IOP They are not recommended as primary procedures

Issues requiring further attention

As there is a paucity of studies on the surgical management of PACG, there is

a need for:

• Long term data on the various forms of surgery for PACG;

• Randomized controlled trials in particular to investigate the role of lens ex-traction and goniosynechialysis in PACG

Consensus Statements

• Laser peripheral iridotomy is recommended as the primary procedure in eyes with PACG

Comment: LPI can be performed easily on an outpatient basis and patients

can then be monitored for response to treatment This will allow time to undertake elective surgery in those with uncontrolled IOP, those with ad-vanced disease or with co-existing cataract LPI also serves as prophylaxis against acute angle closure

• There is lack of evidence for recommending primary incisional surgery (without laser PI) in eyes with PACG

• Trabeculectomy may be performed to lower IOP in eyes with chronic PAC (G) insufficiently responsive to laser or medical therapy

• There is insufficient evidence for deciding which cases with PACG should undergo cataract surgery alone (without trabeculectomy)

Comment: Cataract surgery alone may be considered in eyes with mild

de-gree of angle closure (less then 180 dede-grees of PAS), mild optic nerve/ visual field damage or those that are not on maximal tolerated medical therapy

• There is lack of evidence for recommending lens extraction alone in eyes with more advanced PACG

Comment: Published studies to date have been non-randomized with small

sample sizes and short follow up

• Combined cataract and glaucoma surgery in certain eyes may be useful to control IOP and restore vision

Comment: There is limited published evidence about the effectiveness of

combined cataract extraction and trabeculectomy in eyes with PACG There

is a need for studies comparing this form of surgery with separately staged cataract extraction and trabeculectomy

• There is limited evidence about the effectiveness of goniosynechialysis in the management of PACG

References

1 Ritch R, Lowe RF Angle closure glaucoma In: Ritch R, Shields MB, Krupin T (eds) The Glaucomas St Louis: CV Mosby, 1996:801.

2 Wang N, Wu Z, Liu H Mechanism and etiology of primary chronic angle closure glau-coma Yen KO Hsueh Pao 1994;10:186-192.

3 Kim YY, Jung HR Clarifying the nomenclature for primary angle-closure glaucoma Surv Ophthalmol 1997;42:125-136.

4 Gazzard G, Friedman DS, Devereux JG, Chew PT, Seah SK A prospective ultrasound biomicroscopy evaluation of changes in anterior segment morphology after laser iridotomy

in Asian eyes Ophthalmology 2003;110:630-638.

5 Hung PT, Chou LH Provocation and mechanism of angle-closure glaucoma after iridec-tomy Arch Ophthalmol 1979;97:1862-1864.

6 Ritch R, Lowe RF, Reyes A Therapeutic overview of angle-closure glaucoma In: Ritch R, Shields MB, Krupin T (eds) The glaucomas St Louis: CV Mosby, 1989:858.

7 Li PS, Lai JS, Lam DS Anterior chamber depth in plateau iris syndrome and papillary block as measured by ultrasound biomicroscopy Am J Ophthalmol 2004;137:1169-1170.

8 He M, Foster PJ, Johnson GJ, Khaw PT Angle-closure glaucoma in East Asian and

Euro-pean people Different diseases? Eye 2006;20:3-12.

9 Sihota R, Lakshmaiah NC, Walia KB, et al The trabecular meshwork in acute and chronic angle closure glaucoma Indian J Ophthalmol 2001;49:255-9.

10 Foster PJ, Machin D, Wong TY, et al Determinants of intraocular pressure and its associa-tion with glaucomatous optic neuropathy in Chinese Singaporeans: the Tanjong Pagar Study Invest Ophthalmol Vis Sci 2003;44:3885-3891.

11 Aung T, Lim MCC, Chan YH, Rojanapongpun P, Chew PT, EXACT Study Group Con-figuration of the Drainage Angle, Intraocular Pressure and Optic Disc Cupping in Subjects with Chronic Angle Closure Glaucoma Ophthalmology 2005;112:28-32.

12 Gelber EC, Anderson DR Surgical decisions in chronic angle-closure glaucoma Arch Ophthalmol 1976;94:1481-1484.

13 Playfair TJ, Watson PG Management of chronic or intermittent primary angle-closure glaucoma: a long-term follow-up of the results of peripheral iridectomy used as an initial procedure Br J Ophthalmol 1979;63:23-28.

14 Hoskins HD Jr, Kass MA Becker-Shaffer’s Diagnosis and Therapy of the Glaucomas: Angle-closure Glaucoma with Pupillary Block St Loius: CV Mosby, 1989:208-237.

15 Shields MB Textbook of Glaucoma: Primary angle closure glaucoma Baltimore: Will-iams & Wilkins, 1992:198-219.

16 Salmon JF Long-term intraocular pressure control after Nd-YAG laser iridotomy in chronic angle-closure glaucoma J Glaucoma 1993;2:291-296.

17 Yamamoto T, Shirato S, Kitazawa Y Treatment of primary angle-closure glaucoma by argon laser iridotomy: a long-term follow-up Jpn J Ophthalmol 1985;29:1-12.

18 Alsagoff Z, Aung T, Ang LPK, Chew PTK Long-term clinical course of primary

angle-closure glaucoma in an Asian population Ophthalmology 2000;107:2300-2304.

19 Rosman M, Aung T, Ang LPK, Chew PTK, Liebmann J, Ritch R Chronic Angle-Closure with Glaucomatous Damage: Long-term Clinical Course in a North American population and comparison with an Asian Population Ophthalmology 2002;109:2227-2231.

20 Nolan WP, Foster PJ, Devereux JG, et al YAG laser iridotomy treatment for primary angle closure in east Asian eyes Br J Ophthalmol 2000;84:1255-1259.

21 Ritch R The treatment of chronic angle-closure glaucoma Ann Ophthalmol

1981;13:21-23.

22 Quigley HA Long-term follow-up of laser iridotomy Ophthalmology 1981;88:218-224.

23 Robin AL, Pollack IP Argon laser peripheral iridotomies in the treatment of primary angle-closure glaucoma: long-term follow-up Arch Ophthalmol 1982;100:919-923.

24 Gieser DK, Wilensky JT Laser iridectomy in the management of chronic angle-closure

glaucoma Am J Ophthalmol 1984;98:446-450.

25 Schwartz LW, Moster MR, Spaeth GL, Wilson RP, Poryzees E Neodynium-YAG laser iridectomies in glaucoma associated with closed or occludeable angles Am J Ophthalmol 1986;102:41-44.

26 Sihota R, Gupta V, Agarwal HC Long-term evaluation of trabeculectomy in primary open angle glaucoma and chronic primary angle closure glaucoma in an Asian population Clin Exp Ophthalmol 2004;32:23-28.

27 Watson PG, Barnett F Effectiveness of trabeculectomy in glaucoma Am J Ophthalmol 1975;79:831-845.

28 Salmon, HF, Swanevelder, SA, Donald, MA The dimensions of eyes with chronic angle-closure glaucoma J Glaucoma 1994;3:237.

29 Ritch R Glaucomas secondary to lens intumescence and dislocation In: Ritch R, Shields

MV (eds) The Secondary Glaucomas, St Louis, MO, CV Mosby, 1982;131-149.

30 Wishart PK, Atkinson PL Extracapsular cataract extraction and posterior chamber lens implantation in patients with primary chronic angle-closure glaucoma: effect on intraocu-lar pressure control Eye 1989;3:706-712.

31 Greve EL Primary angle closure glaucoma: Extracapsular cataract extraction or filtering procedure? International Ophthalmology 1988;12:157-162.

32 Acton J, Salmon JF, Scholtz R Extracapsular cataract extraction with posterior chamber lens implantation in primary angle-closure glaucoma J Cataract Refract Surg 1997;23:930-934.

33 Gunning, FP, Greve EL Lens extraction for uncontrolled glaucoma J Cataract Refract Surg 1998;24:1347-1356.

34 Roberts TV, Francis IC, Lertusumitkul S, et al Primary phacoemulsification for uncon-trolled angle-closure glaucoma J Cataract Refract Surg 2000;26:1012-1016.

35 Hayashi K, Hayashi H, Nakao F, Hayashi F Changes in anterior chamber angle width and depth after intraocular lens implantation in eyes with glaucoma Ophthalmology 2000;107:698-703.

36 Obstbaum SA Cataract surgery and its effect on intraocular pressure J Cataract Refract

Surg 1999;25:877.

37 Tow SLC, Aung T, Oen FTS, Seah SKL Combined phacoemulsification, intraocular lens implantation and trabeculectomy in Asian patients with chronic angle closure glaucoma Int Ophthalmol 2001;24:283-289.

38 Lai JS, Tham CC, Chan JC, Lam DS Phacotrabeculectomy in treatment of primary angle-closure glaucoma and primary open-angle glaucoma Jpn J Ophthalmol 2004;48:408-411.

39 Campbell DG, Vela A Modern goniosynechialysis for the treatment of synechial angle-closure glaucoma Ophthalmology 1984;91:1052-1060.

40 Teekhasaenee C, Ritch R Combined phacoemulsification and goniosynechialysis for un-controlled chronic angle-closure glaucoma after acute angle-closure glaucoma Ophthal-mology 1999;106:669-675.

41 Seah SKL, Gazzard G, Aung T Intermediate-term Outcome of Baerveldt Glaucoma Im-plants in Asian Eyes Ophthalmology 2003;110:888-894.

42 Chung AN, Aung T, Wang JC, Chew PTK Surgical outcomes of combined phacoemulsifi-cation and glaucoma drainage implant surgery for Asian patients with refractory glaucoma and cataract Am J Ophthalmol 2004;137:294-300.

Jeffrey Liebmann (podium), Robert N Weinreb, David S Friedman, Paul Foster, Aung Tin (left to right).

Robert Ritch providing a historical perspective.

Robert Ritch discussing gonioscopy.

LASER AND MEDICAL

TREATMENT OF PRIMARY ANGLE

CLOSURE GLAUCOMA

Co-chairs: Robert Ritch, Winnie Nolan and Dennis Lam

Introduction

The aim of this section is to discuss the current practice for non-surgical man-agement of PACG A summary of the literature and strength of evidence for the interventions of laser iridotomy, argon laser peripheral iridoplasty and medical

treatment will be given.

Laser Peripheral Iridotomy (LPI)

Laser peripheral iridotomy (LPI) replaced surgical iridectomy as first-line treat-ment of PACG in the late 1970s with the advent of argon and then Nd:YAG laser technology The Nd:YAG laser was shown in prospective studies to be as effec-tive as surgical iridectomy and argon laser iridotomy.1-3 It has the advantages of using less total energy than argon laser and is theoretically less likely to cause damage to the lens and retina

Mechanism of action

Laser iridotomy alleviates pupillary block by allowing aqueous to bypass the pupil The pressure differential between anterior and posterior chambers is elimi-nated; the iris loses its convex configuration and falls away from the trabecular meshwork, resulting in the partial or complete opening of the angle.4

Indications for LPI

Prevention of acute angle closure: Lowe and Snow reported that iridectomy was

effective in preventing a subsequent episode of angle closure in fellow eyes of cases with acute angle closure Left untreated these eyes had 50% risk of an attack of angle closure over five years.5,6 Fellow eyes of PAC/PACG affected

Angle Closure and Angle Closure Glaucoma, pp 37-54

edited by Robert N Weinreb

© 2006 Kugler Publications, The Hague, The Netherlands

Robert Ritch

eyes should be treated with LPI with the aim of the above points The exception

to this is in cases where the fellow eye is pseudophakic

Long-term IOP control: In patients presenting with PAC/PACG who have

el-evated IOP one of the aims of LPI treatment is to try and achieve target IOP

levels by treating the reversible component of the disease, i.e., appositional angle

closure

Prevention of PAS formation and progressive glaucomatous optic nerve damage:

By eliminating appositional closure due to pupillary block and thereby remov-ing the principal causal mechanism underlyremov-ing PAS development And by re-lieving appositional closure, therefore theoretically either lowering co-existing raised IOP, or preventing future IOP rises which lead on to development or progression of glaucomatous optic neuropathy

Techniques for performing LPI

Optimal size and location of LPI: While some recommend that the LPI should

be positioned in the peripheral one third of the iris between 11:00 and 1:00 o’clock, in order to minimize visual symptoms which patients may suffer if the LPI is placed at the lid margin or in the interpalpebral region, others routinely place the LPI at the 3 and 9 o’clock positions.7 Where iris crypts are present, the iris will be thinner and these sites, if in a suitable position, should be used for LPI

Fleck calculated that an iridotomy should be a minimum size of 15 microns

in order to prevent pupillary block but suggested aiming for a size of 150-200 microns.8 One of the factors incorporated into the model he used for the calcu-lations was the iris thickness As brown Asian irides are thicker and more bulky than blue ones they probably require a larger iridotomy

LPI methods

Argon LPI

Argon laser began to replace surgical iridectomy as a safer, non-invasive method

of making an iridotomy in the late 1970s It was demonstrated to be safe and effective,9 but required melanin for tissue absorption of the energy, making it less easy to penetrate lightly pigmented blue irides

Nd:YAG LPI

The Nd:YAG laser replaced argon as the most common means of performing LPI in the late 1980s The Q-switched mode of the Nd:YAG laser causes photodisruption of tissues by the formation of a high energy ionic plasma at the

location of focus of very intense energy It has the advantage of not requiring the presence of melanin pigment for iris absorption The overall energy required to produce an iridotomy is lower than that required with argon laser Nd:YAG la-sers are usually smaller and portable which can be useful where treatment of patients in the community is necessary The Nd:YAG LPI is the method of choice for Caucasian angle closure patients with blue or light brown irides

Sequential argon / Nd:YAG LPI

In patients with brown irides, large amounts of energy may be required to achieve

a patent PI when using the Nd:YAG laser This of particular relevance in Asian and African populations, but also applies to some Caucasian individuals Argon laser pre-treatment to thin the iris results in the need for less energy with the Nd:YAG laser, which is then used to penetrate the iris and create an iridotomy.10,11 The coagulative effect of the argon laser reduces the risk of haemorrhage from the iridotomy site Frequency-doubling continuous wave Nd:YAG lasers can be used for the same purpose as the argon laser

Guidelines for performing LPI

• Patients presenting with newly diagnosed PAC or PACG with markedly el-evated IOP should be treated with topical and systemic medications to achieve

a safe IOP level (< 30 mmHg) prior to undergoing LPI;

• Pre-treat the eye with one drop of Pilocarpine 2 to constrict the pupil and use an alpha-agonist (brimonidine or apraclonidine) before and after laser treatment to minimize the risk of post laser IOP spikes;12

• Topical anesthesia;

• Lens: Abraham lens or Wise lens with coupling fluid

Nd:YAG laser PI (suggested settings)

Check that defocus is set to zero Some surgeons start with relatively low power (1-3 mJ) to thin the iris, and others start with higher power (5-8 mJ) to quickly penetrate the iris A gush of pigment from the posterior chamber signals patency

of the iridotomy Once a hole has been made in the iris, it should be enlarged horizontally to achieve an adequate size iridotomy (If possible the energy should

be lowered for enlarging the iridotomy)

Sequential argon / Nd:YAG PI (suggested settings)

Argon laser settings

Stage 1: (optional): 50 micron spot size 100mW 0.05 seconds duration Thirty

shots in rosette pattern to thin the iris This helps avoid large, adherent bubbles with higher power